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| United States Patent |
6,102,377
|
|
Doughty
|
August 15, 2000
|
Wet scrubbing spray apparatus for removing sulfur oxides from combustion
effluents
Abstract
Sulfur oxides (SO.sub.x) are scrubbed from combustion effluents with
economies in capital and operating costs by virtue of an arrangement of
spray header piping and nozzles which permits ease of access for service
with reduced spacing (e.g., 0.5 to 1.25 meters) between spray levels. At
least two spray levels in a spray zone include a plurality of spray header
pipes arranged parallel to the other spray header pipes within a spray
level and vertically parallel to spray header pipes in at least one
adjacent spray level. Each of the spray levels includes a plurality of
spray nozzles extending from said spray headers. A majority of nozzles in
a reference spray level are positioned such that lines drawn between them
form a pattern of squares with the nozzles located at the corners of the
squares. And, a majority of nozzles in an adjacent spray level are
positioned over the centers of squares defined by four nozzles in the
reference spray level. Among other advantages of the invention are the
ability to support the spray headers by trussing two adjacent headers
together in a self-supporting arrangement or by vertically-suspended
hangars which do not interfere with access for service.
| Inventors:
|
Doughty; Joseph V. (Knoxville, TN)
|
| Assignee:
|
ABB Environmental Services, Division of ABB Flakt, Inc. (Knoxville, TN)
|
| Appl. No.:
|
807867 |
| Filed:
|
February 26, 1997 |
| Current U.S. Class: |
261/117; 95/195; 95/224; 95/235; 96/236; 96/265; 261/DIG.9 |
| Intern'l Class: |
B01D 047/06 |
| Field of Search: |
95/223,224,189,195-197
261/117,116,DIG. 9
55/223,228,229
|
References Cited
U.S. Patent Documents
| 1222541 | Apr., 1917 | Donham | 95/224.
|
| 2180586 | Nov., 1939 | Gustafsson | 261/117.
|
| 2858903 | Nov., 1958 | Goetz et al. | 261/116.
|
| 3140163 | Jul., 1964 | Hausberg | 261/116.
|
| 3995006 | Nov., 1976 | Downs et al. | 423/243.
|
| 4495113 | Jan., 1985 | Kice | 261/117.
|
| 4776989 | Oct., 1988 | Harper et al. | 261/97.
|
| 5173093 | Dec., 1992 | Johnson et al. | 95/224.
|
| 5451250 | Sep., 1995 | Gohara et al. | 95/224.
|
| 5474597 | Dec., 1995 | Halldin | 95/199.
|
| 5512072 | Apr., 1996 | Laslo | 261/117.
|
| Foreign Patent Documents |
| 0 024 551 | Mar., 1981 | EP.
| |
| 62-4428 | Jan., 1987 | JP | 261/117.
|
| 2297705 | Aug., 1996 | GB.
| |
Other References
Rader, P.C., Bakke, E., "Incorporating Full-Scale Experience into Advanced
Limestone Wet FGD Designs"; IGCI Form '91, Washington, D.C., Sep. 12, 1991
.
|
Primary Examiner: Chiesa; Richard L.
Claims
What is claimed is:
1. An improved wet scrubbing apparatus for reducing the concentration of
SO.sub.x in flue gases, said apparatus comprising an inlet for flue gases,
an outlet for the flue gases, and a spray zone positioned between the
inlet and the outlet, wherein the improvement comprises:
at least two spray levels in said spray zone, each of the spray levels
comprising a plurality of spray header pipes arranged parallel to the
other spray header pipes within a spray level and vertically parallel to
spray header pipes in at least one adjacent spray level spaced by less
than 1.25 meters, wherein
the spray header pipes are each supported at one end by a wall which
defines part of the spray zone and are supported through its length by a
truss structure and a vertically adjacent spray header pipe to create a
beam structure between the two to greatly increase the ability of the
header pipes to support weight.
2. A wet scrubbing apparatus according to claim 1, wherein:
the spray header pipes are each supported at one end by a wall which
defines part of the spray zone and are supported at the other end by a
hanger which is suspended vertically to attach at least two
vertically-spaced spray header pipes.
3. A wet scrubbing apparatus according to claim 1, wherein:
each spray level is fed independently by a feed header, which supplies
slurry to all of the spray header pipes in the spray level.
4. An improvement in a wet scrubbing apparatus for reducing the
concentration of SO.sub.x in flue gases, said apparatus comprising an
inlet for flue gases, an outlet for the flue gases, and a spray zone
positioned between the inlet and the outlet, wherein the improvement
comprises:
said spray zone comprises at least two spray levels, and each of the spray
levels comprises a plurality of spray nozzles supported by spray header
pipes, wherein
the spray header pipes are each supported at one end by a wall which
defines part of the spray zone and are supported at the other end by a
hanger which is suspended vertically to attach at least two
vertically-spaced spray header pipes,
a majority of nozzles in a reference spray level are positioned such that
lines drawn between them form a pattern of squares with the nozzles
located at the corners of the squares,
and a majority of nozzles in an adjacent spray level are positioned over
the centers of squares defined by four nozzles in the reference spray
level, wherein
one spray level and one adjacent spray level are spaced at a distance of
less than about 1.25 meters.
5. A wet scrubbing apparatus according to claim 4, wherein:
each spray level is fed independently by a feed header, which supplies
slurry to spray header pipes feeding spray nozzles in the spray level.
6. A wet scrubbing apparatus according to claim 4, wherein:
each of the spray levels comprising a plurality of spray header pipes
arranged parallel to the other spray header pipes within a spray level and
vertically parallel to spray header pipes in at least one adjacent spray
level.
7. A wet scrubbing apparatus according to claim 4, wherein:
spray header pipes are provided for feeding spray nozzles and each is
supported at one end by a wall which defines part of the spray zone and
each is supported through its length by an adjacent spray header pipe.
8. An improvement in a wet scrubbing apparatus for reducing the
concentration of SO.sub.x in flue gases, said apparatus comprising an
inlet for flue gases, an outlet for the flue gases, and a spray zone
positioned between the inlet and the outlet, wherein the improvement
comprises:
at least two spray levels in said spray zone, each of the spray levels
comprising a plurality of spray header pipes arranged parallel to the
other spray header pipes within a spray level and vertically parallel to
spray header pipes in at least one adjacent spray level,
the spray header pipes are each supported at one end by a wall which
defines part of the spray zone and are supported at the other end by a
hanger which is suspended vertically to attach at least two
vertically-spaced spray header pipes,
and each of the spray levels comprises a plurality of spray nozzles
extending from said spray header pipes, wherein
a majority of nozzles in a reference spray level are positioned such that
lines drawn between them form a pattern of squares with the nozzles
located at the corners of the squares,
and a majority of nozzles in an adjacent spray level are positioned over
the centers of squares defined by four nozzles in the reference spray
level, and wherein
one spray level and one adjacent spray level are spaced at a distance of
less than about 1.25 meters.
9. A wet scrubbing apparatus according to claim 8, wherein:
the spray header pipes are each supported at one end by a wall which
defines part of the spray zone and are supported through its length by an
adjacent spray header pipe.
10. A wet scrubbing apparatus according to claim 8, wherein:
one spray level and one adjacent spray level are spaced at a distance of
from about 0.5 to about 1.0 meters.
Description
TECHNICAL FIELD
The invention relates to improvements facilitating servicing of slurry
spray apparatus and more efficient removal of sulfur oxides (SO.sub.x)
from combustion effluents.
Combustion of carbonaceous materials containing significant amounts of
sulfur, including fossil fuels and waste, is being closely regulated by
governments around the world. Free radicals of sulfur and oxygen are
released and combine at the elevated temperatures involved to produce a
variety of oxides of sulfur, which are referred to as a group as SO.sub.x.
Regulations in many countries require reducing the amounts of sulfur
oxides released to the atmosphere to alleviate the problems associated
with acid rain.
Numerous strategies are being employed to reduce the discharge of SO.sub.x
to the atmosphere. Among these are methods for cleaning sulfur from fuels
prior to combustion, methods for chemically tying up the sulfur during
combustion, and methods for removing the sulfur oxides from combustion
effluents. Among the methods for treating combustion effluents to remove
SO.sub.x, are wet and dry scrubbing. Wet scrubbing technology is well
developed and effective; however, very large equipment has been required
and costs are proportional.
The technology for wet scrubbing combustion effluents to remove SO.sub.x
provides gas-liquid contact in a number of different configurations. Among
the most prominent are the single- and double-loop countercurrent spray
towers and towers which employ both cocurrent and countercurrent sections.
The single-loop, open-tower systems employing calcium carbonate to react
with the SO.sub.x are the simplest in construction and operation. These
systems are often preferred because they can be operated with low pressure
drop and have a low tendency to scale or plug. The advantages of their
simplicity and reliability have, however, been offset in some situations
by their large size. For example, because they do not employ any trays or
packings to improve contact between the effluent and the scrubbing liquid,
tower heights are typically high and many levels of spray nozzles have
been employed to assure good gas-liquid contact. Pumping is a major cost,
which increases with the head of fluid that must be pumped. Taller towers,
thus, increase the cost of construction and operation.
Tower height has been closely related to the number of spray levels and
spacing between the levels. Known nozzle arrangements make servicing a
considerable problem because they decrease access by a serviceman wanting
to move easily among the various pipes and nozzles to find and repair
problems. The prior art has typically provided extra headroom by
increasing the spacing between spray levels so that one spray level could
be serviced at a time without climbing over and around pipes and nozzles.
The increased spacing for headroom can reduce servicing costs, but adds to
the costs of construction and pumping.
There is a need for means and methods to reduce spray level separation and
tower height without compromising the ability to service a spray tower to
enable it to be rapidly returned to service.
BACKGROUND ART
The design and operation of single-loop, countercurrent spray towers
utilizing limestone is discussed by Rader and Bakke, in Incorporating
Full-Scale Experience Into Advanced Limestone Wet FGD Designs, presented
at the IGCI* Forum 91, Sep. 12, 1991, Washington, D.C. (*formerly the
Industrial Gas Cleaning Institute, now the Institute of Clean Air
Companies, Washington, D.C.). Open spray towers (i.e., those not having
packings, trays or other means for facilitating gas-liquid contact) are
simple in design and provide high reliability. They are especially useful
in coal-fired power stations where the evolution of chlorides has caused a
number of problems, including reduced reactivity of the scrubbing solution
and severe corrosion of scrubber internals. Another factor favoring the
use of open spray towers is their inherent low pressure loss and resulting
fan power economy.
In single-loop, countercurrent, open scrubbing towers of the type discussed
by Rader and Bakke, a scrubbing slurry composed of calcium carbonate,
calcium sulfate, calcium sulfite, and other non-reacting solids flows
downwardly while the SO.sub.x -laden effluent gas flows upwardly. The
SO.sub.x, principally S02, is absorbed in the descending scrubbing slurry
and is collected in a reaction tank where calcium sulfite and calcium
sulfate are formed. Desirably, the reaction tank is oxygenated to force
the production of sulfate over sulfite. Once the crystals of sulfate are
grown to a sufficient size, they are removed from the reaction tank and
separated from the slurry. This reference and the one that follows are
incorporated by reference in their entireties for the descriptions of the
known technology of wet scrubbing.
Rader and Bakke note that pumping costs account for about 50% of the total
power requirements of the system. They show spray levels oriented at acute
angles relative to each other and suggest spacing between the levels of
from 5 to 6 feet. The spacing is compelled by what is considered in the
prior art to be appropriate for constraints of the header and support
systems. With spacings between the angularly-oriented spray levels at the
suggested values, tower height and pumping costs will increase. With lower
spacings, servicing will become extremely difficult.
In U.S. Pat. No. 5,173,093, Johnson, et al., describe a single-spray level,
which is designed to take the place of multiple spray levels, in a flue
gas desulfurization system. The arrangement described has a plurality of
spray headers, all arranged in parallel within a common horizontal plane.
The device, having all spray heads in one plane, cannot provide for
efficient overlap of spray patterns to successfully deal with the problem
of gas pass through or channeling.
The prior art does not address the points necessary to reduce tower height
for wet scrubbers for SO.sub.x reduction, while addressing the issue of
servicing in an efficient manner.
DISCLOSURE OF THE INVENTION
It is an object of the invention to provide improved apparatus and
processes for wet scrubbing combustion effluents to remove sulfur oxides.
It is another object of the invention to facilitate servicing of spray
apparatus in wet scrubbers.
It is a more specific object of the invention to reduce the size of
single-loop, open-tower, countercurrent limestone wet scrubbers.
It is yet another object of the invention to improve the design and
location of spray equipment in wet scrubbing towers.
It is a still further object of a preferred embodiment of the invention to
improve the process efficiency of single-loop, open-tower, countercurrent
limestone wet scrubbers by achieving effective liquid to gas contact
within a scrubbing zone of reduced height.
These and other objects are accomplished by the invention, which provides
both improved processes and apparatus for wet scrubbing.
In one aspect, the invention provides an improved wet scrubbing apparatus
for reducing the concentration of SO.sub.x in flue gases, said apparatus
being of the type comprising, an inlet for flue gases, an outlet for the
flue gases, a spray zone positioned between the inlet and the outlet,
wherein the improvement comprises: at least two spray levels in said spray
zone, each of the spray levels comprising a plurality of spray header
pipes arranged parallel to the other spray header pipes within a spray
level and vertically parallel to spray header pipes in at least one
adjacent spray level spaced by less than 1.25 meters.
In another aspect of the invention, the improvement in scrubbers of this
type comprises: employing at least two spray levels in the spray zone with
each of the spray levels comprising a plurality of spray nozzles, wherein
a majority of nozzles in a reference spray level are positioned such that
lines drawn between them form a pattern of squares, with the nozzles
located at the corners of the squares, and a majority of nozzles in an
adjacent spray level are positioned over the centers of squares defined by
four nozzles in the reference spray level.
Preferably, each spray level is fed independently by a feed header, which
supplies slurry to all of the spray header pipes in the spray level. It is
an advantage of the invention that the spray headers can be either
self-supporting with the aid of trussing or suspended by
vertically-suspended hangars without interfering with servicing or
requiring the 5 to 6 feet spacing required by prior art wet scrubbers.
In another aspect, the invention improves a process of the type where a
flow of flue gas containing SO.sub.x is directed upwardly through a
vertical scrubbing tower, a spray of an aqueous slurry of SO.sub.x
-reducing reagent is introduced from a plurality of spray levels within a
spray zone to contact the flue gas while descending through the tower
countercurrently to the flow of flue gas, the slurry is collected and a
portion of it is recycled for contact with the flue gases, wherein the
improvement comprises: providing at least two spray levels in said spray
zone, each of the spray levels comprising a plurality of spray header
pipes arranged parallel to the other spray header pipes within a spray
level and vertically parallel to spray header pipes in at least one
adjacent spray level spaced by less than 1.25 meters.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will be better understood and its advantages will be better
appreciated from the following detailed description, especially when read
in light of the accompanying drawings, wherein:
FIG. 1 is a schematic perspective view of a preferred embodiment of the
invention employing a new spray nozzle arrangement in a single-loop,
open-tower, countercurrent limestone wet scrubber;
FIG. 2 is perspective view, broken away from FIG. 1, showing the detail of
a preferred nozzle arrangement for two adjacent spray levels;
FIG. 3 is cross-sectional view taken along plane 3--3 in FIG. 1;
FIG. 4 is a cross-sectional view taken along plane 4--4 in FIG. 1;
FIG. 5 is cross-sectional view taken along plane 5--5 in FIG. 3;
FIG. 6 is a cross-sectional view taken along plane 6--6 in FIG. 3; and
FIG. 7 is a schematic of a side elevation showing the major components of a
typical open tower scrubber modified according to the invention.
Industrial Applicability
The improvements of the invention have preferred application to utility
boiler flue gases, and this embodiment will be described for purposes of
illustrating the invention and its advantages. The invention is not
limited to this embodiment and effluents from all types of combustion
sources and utilizing packed or other scrubbing apparatus are envisioned.
FIG. 1 illustrates a single-loop, open-tower, countercurrent limestone wet
scrubbing tower for removing sulfur oxides, principally as SO.sub.2, from
combustion effluents. See also FIG. 7, which is a schematic of a side
elevation showing the major components of a typical open tower scrubber
modified according to the invention. This is the preferred embodiment of
the invention, but the invention has applicability to cocurrent flow
scrubbers as well as other configurations and design, including those with
spray nozzles that direct flow of scrubbing fluid both upwardly and
downwardly.
The preferred form of wet scrubbers, employ alkaline SO.sub.x -reducing
reagents, including calcium compounds like lime and limestone, sodium
compounds like sodium hydroxide and sodium carbonate, and ammonium
compounds, as the art has described as useful for SO.sub.x -reducing
reagents in their various commercial forms. Almost all accessible forms of
calcium carbonate found in nature contain minor quantities of relatively
inert materials, such as free silica, magnesium carbonate or dolomite,
iron oxides, alumina, and so forth. Limestone is a preferred form of
calcium carbonate but can be replaced with another form, if desired. In
addition to limestone, other forms of calcium carbonate include oyster
shells, aragonite, calcite, chalk, marble, marl, and travertine. It can be
mined or manufactured. In this description, the terms calcium carbonate
and limestone are used interchangeably. The limestone is finely divided,
preferably by grinding to achieve a weight median diameter of about less
than 44.mu., and slurried with from about 15 to about 35% water. This and
all percentages set forth herein are based on the weight to the total
composition.
The preferred process arrangement of FIGS. 1 and 7 shows an effluent,
preferably cleaned of particulates, such as by an electrostatic
precipitator or fabric filter, passed via duct 20 to wet scrubbing tower
100 wherein it flows upwardly, countercurrent to a spray of an aqueous
slurry which contains limestone discharged within a vertical scrubbing
section 110 including a spray zone 120 having four spray levels 121, 122,
123 and 124. FIGS. 2-6 and the description that follows will explain the
arrangement and spacing in more detail. From the scrubbing section 110,
the gas continues through gas outlet duct 130. The tower is configured to
direct a flow of flue gas upwardly through the vertical scrubbing section.
The scrubbed effluent is significantly freed of entrained droplets of
liquid by a suitable entrainment separator 140 and discharged to a stack
(not shown).
The scrubbing slurry falling through the vertical scrubbing section 110 is
collected in reaction tank 150. The reaction tank 150 is preferably of a
size suitable to permit reaction of the SO.sub.2 with the calcium
carbonate to form crystals of gypsum having a weight median diameter
sufficiently large to assure their separation by suitable means, such as a
hydrocyclone 160, for removal from the system. A stream of the slurry is
constantly withdrawn from the tank via line 152 and passed through
hydrocyclone 160 or other suitable separation device to provide one stream
153 for discharge and another 154 for recycle to the scrubbing zone.
Recycle to the scrubbing zone is done via lines 155-158. Preferably, each
line is associated with a separate pump means, e.g., 159 in line 158. In
this manner, each of the scrubbing levels is fed from a dedicated supply
header, e.g., headers 125-128.
FIG. 3 illustrates the close alignment and configuration of
vertically-parallel spray header pipes in four spray levels. The flanged
ends of each, e.g., flange 129 on the illustrated spray header in spray
level 121, facilitates connection to the supply headers 125-128. FIGS. 2
and 3 also illustrate how the vertical alignment and close adjacent spray
levels (spaced by less than 1.25 meters) enable self supporting the spray
levels by forming a truss structure 151 between two adjacent spray header
pipes. The connection in this or equivalent manner creates a beam
structure between the two and greatly increases the ability of the headers
to support weight. The preferred spacing between at least two of the spray
levels, two closely adjacent spray levels, is from about 0.5 to about 1.25
meters, more narrowly from about 0.5 to about 1 meters, e.g., about 0.75
meters in one exemplary embodiment. These spacings are from the centerline
of a spray header pipe in one level to the centerline of its mate in the
adjacent level.
Referring to FIG. 4, it is easy to see how a service man can walk
unobstructed through the interior of the scrubber to service two spray
levels from a scaffolding or flooring supported at one level. There is
sufficient headroom between the levels as indicated, and there are no
obstructions to step over or walk around on a clear path from one wall of
the scrubbing tower to the other. Servicing is facilitated if the
elevation of the spray levels above the lowermost, is sufficient to enable
a man to stand up--e.g., the height from level 121 to level 123 being at
least 1.5 meters and preferably at least about 1.8 meters.
FIG. 5 shows one illustrative spray level, with the nozzles (indicated by
the circles, e.g., 161, at the end of lines, e.g., 162, feeding them from
a spray header, e.g., 121) arranged in a square pattern. Note that in this
embodiment, a majority of the nozzles (preferably all, except those near
the periphery) are at the corners of the squares in the pattern. FIG. 6 is
then referenced to show the overlapping of the patterns of two adjacent
levels. Here the nozzles of the illustrated closely adjacent level are
located so that a majority is positioned at the center of a square in the
pattern of the other illustrated level. This pattern has special advantage
when employing the parallel, closely-spaced adjacent spray levels because
the gas flow past the nozzles in one level will be diverted directly into
the spray of the nozzles in the adjacent level. Reference to FIG. 7 (see
also FIGS. 4 and 6 for the detail of nozzle arrangement) will help
visualize how the spray from one nozzle at a corner of a square (say, in
level 124) will be directed in the next, close-adjacent level (in this
example, 123) where a nozzle is located at the center of each above
square. With larger, conventional spacings between levels, the effect of
this flow diversion will not occur or be as pronounced. With larger
spacings, the flow is enabled to reorganize to the extent that bypass of
the next level of nozzles can occur. Provision of the closely adjacent
levels of the invention provides more intimate, vigorous contact than can
be otherwise achieved.
FIG. 7 shows the height of the scrubbing zone as 110, being the distance
between the top of the liquid in the tank 150 and the uppermost spray
level, 121. This is the head of liquid that must be pumped. This height is
affected by the height of the spray zone 120. Thus, as the height of the
spray zone 120 is decreased by the invention, the head of liquid that must
be pumped is decreased. This is an advantage of the invention, and it is
surprising that pumping costs can be reduced while achieving improved
gas-liquid contact. These advantages are especially surprising when viewed
in connection with improvements in service accessibility that are also
achieved.
A preferred form of nozzle is a centrifugal nozzle, which forms a spray at
an angle .alpha. of within the range of from about 90 to about
140.degree., preferably about 120.degree.. One suitable nozzle is a
Whirljet 300 gallon per minute nozzle available from Spraying Systems Co.,
Wheaton, Ill. Droplet sizes are preferably in the range of from about 100
to about 6000.mu., typically about 2000.mu., Sauter mean diameter as
measured by a Malvern Particle Analyzer. Other nozzle designs can be
employed, including those that direct flow of scrubbing fluid both
upwardly and downwardly.
The above description is for the purpose of teaching the person of ordinary
skill in the art how to practice the invention, and it is not intended to
detail all of those obvious modifications and variations of it which will
become apparent to the skilled worker upon reading the description. It is
intended, however, that all such obvious modifications and variations be
included within the scope of the invention which is defined by the
following claims. The claims are meant to cover the claimed elements and
steps in any arrangement or sequence that is effective to meet the
objectives there intended, unless the context specifically indicates the
contrary.
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